DE102009002498A1 - Device for handshake correction and digital camera containing it - Google Patents

Abstract

Provided are a handshake correction device and a digital camera including the handshake correction device. The handshake correction device comprises: a correction lens module including a correction lens and a correction lens support plate; a base movably supporting the carrier plate; first and second drive units which move the carrier plate; and third and fourth drive units that move the carrier plate. The first and second drive units are arranged such that a line of action of the drive force exerted on the carrier plate by the first and second drive units passes through a center of mass of the correction lens module. The third and fourth drive units are arranged such that a line of action of the drive force exerted on the carrier plate by the third and fourth drive units passes through a center of mass of the correction lens module.

Description

Reference to related patent application

This application claims the priority of Korean Patent Application No. 10-2008-0051067 filed with the Korean Intellectual Property Office on May 30, 2008, the disclosure of which is incorporated herein by reference in its entirety.

Background of the invention

Field of the invention

The The present invention relates to an apparatus for handshake correction and a digital camera containing them. In particular, it concerns the present invention provides an apparatus for handshake correction, which the blurring of an image, which by the hand movement ("hand shaking") of the photographer taking a picture using of a digital camera is reduced, and a digital one Camera containing the device for handshake correction.

Description of the Related Art

in the In general, a digital camera is a device which generates digital files of fixed or moving pictures and / or stores. Examples of such digital cameras include a digital still camera (DSC), a digital video camera (DVC), digital cameras installed in mobile phones, and similar.

Since a large number of such digital cameras are currently in use, there is an increased demand from consumers for products that provide high quality still images and / or moving images. As a result, there is an increased demand for digital still cameras which include a handshake correction device to prevent the decrease in the sharpness of the images caused by hand movements of the photographer during use of the digital camera. A conventional handshake correction apparatus performs a handshake correction function by moving a handshake correction lens or an image forming apparatus. 1 FIG. 12 is a view illustrating an example of a portion of a conventional handshake correction device that performs a handshake prevention function by moving a handshake correction lens.

According to 1 For example, the conventional handshake correction device includes a correction lens support plate 13 which carries a correction lens (not shown) and a base 20 which the correction lens support plate 13 carries so that it is movable along a plane. In 1 is a correction lens (not shown) in an opening portion of the correction lens support plate 13 used. To the correction lens support plate relative to the base 20 to move are a first drive unit 31 which the correction lens support plate 13 moved in a first direction, and a second drive unit 32 which the correction lens support plate 13 moved in a second direction, on the correction lens support plate 13 arranged. Furthermore, a first detection unit detect 41 and a second detection unit 42 , which on the corrective lens support plate 13 are arranged, the extent of movement of the correction lens and / or the correction lens support plate 13 relative to the base 20 ,

If the conventional handshake correction device is installed in a digital camera, the base becomes 20 installed in a housing of the digital camera, and even if the Ba sis 20 the device for handshake correction due to shaking of the housing of the digital camera, z. B. is shaken by a hand movement, the correction lens support plate 13 relative to the base 20 moved together with the correction lens; as a result, light passing through other lens sections, including the correcting lens, falls onto predetermined portions of the image-forming apparatus despite the jarring of the digital camera. Accordingly, a sharp fixed or moving image can be obtained without blurring.

In the 1 A conventional handshake correction device is an integrated shutter handshake correction device in which a shutter is provided 51 and a shutter drive unit 53 are integrally formed in the device for handshake correction. Accordingly, as in 1 shown to the shutter 51 and the shutter drive unit 53 to arrange the shape of the correction lens support plate 13 with respect to a crossing point COA of the correction lens and the optical axis passing through the correction lens, which can be regarded as the center of the handshake correction device, not symmetrical. As a result, a center of mass CM of a correction lens module deviating from the correction lens and the correction lens support plate deviates 13 includes, from the optical axis passing through the crossing point COA of the correction lens and from the optical axis passing through the correction lens. Accordingly, a center of force CF, which corresponds to the crossing point of a line of action of the driving force F _{V of} the first drive unit 31 which the correction lens support plate 13 moved in a first direction, and a line of action of the driving force F _{H of} a second drive unit 32 which the correction lens support plate 13 is moved in a second direction, not the center of mass CM of the correction lens module. In this way, a torque is generated when the correction lens module by the first drive unit 31 and the second drive unit 32 is moved. When an undesired torque as described above is generated in the operation of the handshake correction device, the handshake prevention function of the handshake correction device is lowered.

In addition, as in 1 shown, the center of force CF, which is the intersection point of the line of action of the driving force F _{V of} the first drive unit 31 and the line of action of the driving force F _{H of} the second drive unit 32 not the crossing point COA of the correction lens and the optical axis passing through the correction lens, which may be regarded as the center of the handshake correction device. Accordingly, as in the view of an illustrative example of a portion of another conventional handshake correction apparatus of FIG 2 is shown, the positions of the first drive unit 31 and the second detection unit 41 reversed, and the positions of the second drive unit 32 and the second detection unit 42 interchanged to the center of force CF, which is the intersection point of the line of action of the driving force F _{V of} the first drive unit 31 and the line of action of the driving force F _{H of} the second drive unit 32 9 is to be brought into correspondence with the crossing point COA of the correction lens and the optical axis passing through the correction lens, which may be regarded as the center of the handshake correction device.

Although the first and second drive units 31 and 32 for easier representation in the 1 and 2 are small, is the actual size of the first and second drive units 31 and 32 considerably, and it is not easy to do this, as in 2 represented to arrange. Since the first detection unit 41 and / or the second detection unit 42 , as in 2 shown closer to the shutter drive unit 53 are arranged as in 1 , you can also through the shutter drive unit 53 be influenced, causing the movement of the corrective lens support plate 13 can not be accurately detected.

Summary of the invention

The The present invention provides an apparatus for handshake correction available, which has an undesirable effect, by the hand movement ("hand-shaking") of the Photographers taking a picture using a digital image Camera is caused, reduced. The present invention also provides a digital camera, which comprises the device for handshake correction.

According to one Embodiment of the present invention is a device provided for handshake correction. The device for handshake correction comprises: a correction lens module which a correction lens and a correction lens support plate, which carries the correction lens comprises; a base, which the correction lens support plate along a first axis, which is perpendicular to an optical axis of the correction lens, and along a second axis perpendicular to the optical axis Axis and the first axis extends, carries movable; first and second drive units, which the correction lens support plate move so that the correction lens support plate along the first axis can be moved; and third and fourth drive units, which move the correction lens support plate such that the correction lens support plate along the second axis can be moved, wherein the first and second drive units are arranged such that a line of action of the driving force, on the correction lens support plate through the first and second Drive units is exercised by the center of mass of the correction lens module, and the third and fourth drive units are arranged such that a line of action the driving force applied to the correction lens plate by the third and fourth drive units are exercised, passes through a center of mass of the correction lens module.

Of the The center of mass of the correction lens module can be along the optical Be positioned axis of the correction lens.

The Line of action of the driving force acting on the corrective lens carrier plate is exercised by the first drive unit, and the Line of action of the driving force acting on the corrective lens carrier plate is exercised by the second drive unit can each parallel to the first axis.

The Line of action of the driving force acting on the corrective lens carrier plate is exercised by the third drive unit, and the Line of action of the driving force acting on the corrective lens carrier plate is exercised by the fourth drive unit can each parallel to the second axis.

The correction lens module may further comprise a magnet mounted on the correction lens carrier The first to fourth drive units may comprise coils which are arranged on the base.

The Handshake correction device may further comprise a yoke, which is arranged on the base opposite the magnet is, wherein the correction lens support plate between the Yoke and the base is arranged and the correction lens module through Attention between the magnet and the yoke rest snugly against the base can.

The first drive unit and the third drive unit can be arranged on a first side of the correction lens, and the second drive unit and the fourth drive unit can be arranged on a second side of the correction lens.

The Handshake correction device can also be a Cover associated with the base includes the correction lens module cover, wherein the cover a first detection unit, which the movement of the corrective lens support plate along the detected first axis, and a second detection unit, which the movement of the correction lens support plate along the second Axis detected includes.

each The first and second detection units may be a Hall sensor include.

The first drive unit and the third drive unit can be arranged on a first side of the correction lens, and the second drive unit and the fourth drive unit can be arranged on a second side of the correction lens, and the first detection unit may be arranged on the first side and the second detection unit may be on the second side the correction lens, or the first detection unit may be disposed on the second side, and the second detection unit may be arranged on the first side of the correction lens.

The Apparatus for handshake correction may further comprise: a Shutter, which shield light incident on the correction lens can; and a shutter drive unit which holds the shutter moved to shield light incident on the correction lens, wherein the shutter drive unit is arranged such that the positions of the first detection unit and the second detection unit do not overlap when passing along the optical axis to be viewed as.

According to one Another embodiment of the present invention a digital image processing device available ge represents which the above-described device for handshake correction includes.

Brief description of the drawings

The above and other features and advantages of the present invention are described by a detailed description of exemplary embodiments with reference to the accompanying drawings can be seen, wherein:

1 Fig. 10 is a view illustrating an example of a portion of a conventional handshake correction apparatus;

2 Fig. 10 is a view illustrating an example of a portion of another conventional handshake correction apparatus;

3 is a perspective view showing an example of a portion of a device for handshake correction according to ei

ner embodiment of the present invention illustrated; the 4A and 4B Represent views illustrating examples of portions of the handshake correction device of FIG 3 according to an embodiment of the present invention;

5 an exploded perspective view showing an example of the device for handshake correction of 3 illustrated in accordance with an embodiment of the present invention;

6 Fig. 11 is an exploded perspective view illustrating an example of a handshake correction apparatus according to another embodiment of the present invention;

7 Fig. 12 is a perspective view illustrating an example of a handshake correction apparatus according to another embodiment of the present invention; and

8th Fig. 12 is a perspective view illustrating an example of a digital camera according to an embodiment of the present invention.

Detailed description of the invention

The The present invention will now be described with reference to the accompanying drawings Drawings in which exemplary embodiments of the Invention are described.

3 FIG. 14 is a perspective view showing an example of a portion of a handshake correction apparatus according to an embodiment. FIG form of the present invention illustrated. 4A FIG. 13 is a view showing an example of a portion of the handshake correction apparatus of FIG 3 from which the correction lens module 110 is removed, illustrated in accordance with an embodiment of the present invention. 4B FIG. 15 is a perspective view showing an example of the correction lens module. FIG 110 from 3 illustrated in accordance with an embodiment of the present invention. 5 FIG. 11 is an exploded perspective view showing an example of the handshake correction apparatus of FIG 3 illustrated in accordance with an embodiment of the present invention.

According to the examples of 3 . 4A . 4B and 5 For example, the handshake correction apparatus according to the present embodiment of the present invention includes a correction lens module 110 , One Base 120 , a first drive unit 131 , a second drive unit 132 , a third drive unit 133 and a fourth drive unit 134 , The corrective lens module 110 includes a correction lens 111 and a correction lens support plate 113 which the correction lens 111 wearing. The corrective lens module 110 is vertically and horizontally symmetrical about its geometric center so that the center of mass CM is at the geometric center of the correction lens module 110 located.

The base 120 wears the corrective lens backing plate 113 such that it is movable along a first axis (x-axis) which is perpendicular to an optical axis (z-axis) and a second axis (y-axis) which is perpendicular to the first axis. Consequently, the correction lens module is 110 which the correction lens support plate 113 includes, movable on the base 120 stored. If a movement z. B. occurs due to a hand movement ("hand-shaking"), and thereby the image obtained from the data in an image-forming device (not shown) is not sharp, thus the correction lens module 110 is moved to correct the hand movement so that the images generated from the data obtained from the image-forming device are sharp.

As described above, the correction lens module 110 , in particular the correction lens carrier plate 113 , relative to the base 120 through first to fourth drive units 131 to 134 to be moved. That is, the first and second drive units 131 and 132 move the correction lens support plate 113 along the first axis (x-axis). The third and fourth drive units 133 and 134 move the correction lens support plate 113 along the second axis (y-axis).

The first drive unit 131 and the second drive unit 132 are arranged such that a line of action of the driving force F _H , on the correction lens support plate 113 through the first drive unit 131 and the second drive unit 132 is applied, by a line of action of the driving force F _H1 , on the correction lens support plate 113 through the first drive unit 131 is exercised, and a line of action of the driving force F _{H2 acting} on the correction lens support plate 113 through the second drive unit 132 is applied through the center of mass CM of the correction lens module 110 runs. Likewise, the third drive unit 133 and the fourth drive unit 134 arranged such that a line of action of the driving force F _V on the correction lens support plate 113 through the first drive unit 131 and the second drive unit 132 is applied, by a line of action of the driving force F _V1 , on the correction lens support plate 113 through the first drive unit 131 is applied, and a line of action of the driving force F _V2 applied to the correction lens support plate 113 through the second drive unit 132 is applied through the center of mass CM of the correction lens module 110 runs. Accordingly, the center of force CF, which is the intersection point of the line of action of the driving forces F _H and F _V , which extends to the correction lens support plate 113 through the first to fourth drive units 131 to 134 is to be exerted by the center of mass of the correction lens module 110 , As in the examples of 3 to 5 shown, the center of mass CM of the correction lens module 110 on the optical axis of the correction lens 111 lie. That is, the crossing point COA of the correction lens 111 and the optical axis of the correction lens 111 may be constructed to correspond to the center of mass CM of the correction lens module 110 equivalent.

In the case of a conventional handshake correction device, as described above, the center of force corresponding to the intersection of the lines of action of the drive forces of the drive units moving the correction lens support plate does not correspond to the center of mass of the correction lens module, thereby inevitably generating a torque. when the correction lens module is moved by the drive units; Accordingly, the handshake prevention function of the handshake correction device is reduced. However, in the handshake correction device according to the present embodiment of the present invention, as described above, the center of force CF, which is the intersection of the lines of action of the driving forces applied to the correction lens support plate 113 through the first to fourth drive units 131 to 134 are exerted by the center of mass CM of the correction lens module 110 , Accordingly, a torque generated while the handshake correction device is in operation can be significantly reduced, whereby the reduction of the handshake prevention function due to the operation of the device for handshake correction can be significantly reduced.

Thus, the line of action of the driving force F _H on the correction lens support plate 113 through the first drive unit 131 and the second drive unit 132 is applied, by the line of action of the driving force F _H1 , on the correction lens support plate 113 through the first drive unit 131 is exercised, and the line of action of the driving force F _{H2 acting} on the corrective lens support plate 113 through the second drive unit 132 finally, through the center of mass CM of the correction lens module 110 runs, the line of action of the driving force F _H1 on the correction lens support plate 113 through the first drive unit 131 is exercised, and the line of action of the driving force F _{H2 acting} on the corrective lens support plate 113 through the second drive unit 132 is exerted, be arranged parallel to the first axis (x-axis).

In this case, the line of action of the driving force F _{H1 acting} on the correction lens support plate 113 through the first drive unit 131 is exercised, and the line of action of the driving force F _{H2 acting} on the corrective lens support plate 113 through the second drive unit 132 is applied, not only parallel to the first axis (x-axis), but also aligned in accordance with the first axis (x-axis), which means that the starting points of the We line of action of the driving force F _H1 on the correction lenses Carrier Plate 113 through the first drive unit 131 is exercised, and the line of action of the driving force F _{H2 acting} on the correction lens support plate 113 is exercised, lying on the first axis (x-axis). To the third drive unit 133 and the fourth drive unit 134 However, as in the example of 4A shown, the line of action of the driving force F _H1 on the correction lens support plate 113 through the first drive unit 131 is exercised, and the line of action of the driving force F _{H2 acting} on the corrective lens support plate 113 is not consistent with the first axis (x-axis).

Accordingly, in this case, as in the example of 4A shown, the first drive unit 131 formed on a first side of the first axis (eg, a line along the line of action of the driving force F _H ), and the second drive unit 132 is disposed on a second side of the first axis, so that the line of action of the driving force F _H on the correction lens support plate 113 through the first drive unit 131 and the second drive unit 132 is applied, by the line of action of the driving force F _H1 , on the correction lens support plate 113 through the first drive unit 131 is exercised, and the line of action of the driving force F _{H2 acting} on the corrective lens support plate 113 through the second drive unit 132 finally, through the center of mass CM of the correction lens module 110 runs.

Thus, as described above, the line of action of the driving force F _V applied to the correction lens support plate 113 through the third drive unit 133 and the fourth drive unit 134 is applied, by the line of action of the driving force F _V1 , on the correction lens support plate 113 through the third drive unit 133 is applied, and the line of action of the driving force F _V2 , which on the correction lens support plate 113 through the fourth drive unit 134 finally, through the center of mass CM of the correction lens module 110 runs, the line of action of the driving force F _V1 on which the correction lens support plate 113 through the third drive unit 133 is applied, and the line of action of the driving force F _V2 , which on the correction lens support plate 113 through the fourth drive unit 134 is exercised to be aligned parallel to the second axis (y-axis).

In this case, the line of action of the driving force F _{V1 acting} on the correction lens support plate 113 through the third drive unit 133 is applied, and the line of action of the driving force F _V2 , which on the correction lens support plate 113 through the fourth drive unit 134 is aligned not only parallel to the second axis (y-axis), but also aligned with the second axis (y-axis), which means that the starting points of the line of action of the driving force F _V1 on the correction lens support plate 113 through the third drive unit 133 is applied, and the line of action of the driving force F _V2 on the correction lens support plate 113 is exercised, lying on the second axis (y-axis). However, the third drive unit 133 and the fourth drive unit 134 can arrange, as in 4A shown, the line of action of the driving force F _V1 on the correction lens support plate 113 through the third drive unit 133 is applied, and the line of action of the driving force F _V2 , which on the correction lens support plate 113 does not match the second axis (y-axis).

Accordingly, in this case, as in 4A shown, the third drive unit 133 formed on a first side of the second axis (y-axis), and the fourth drive unit 134 is disposed on a second side of the second axis (y-axis), so that the line of action of the driving force F _V on the correction lens support plate 113 through the third drive unit 133 and the fourth drive unit 134 is exercised, by the line of action of the driving force F _V1 on the correction lens wearer plate 113 through the third drive unit 133 is applied, and the line of action of the driving force F _V2 on the corrective lens support plate 113 through the fourth drive unit 134 finally, through the center of mass CM of the correction lens module 110 runs.

The first to fourth drive units 131 to 134 can be realized in different ways. For example, the first to fourth drive units 131 to 134 each represent coils that are based on 120 are arranged. In this case, the correction lens module 110 magnets 135 and 136 include on the corrective lens backing plate 113 are arranged, as in examples of 3 to 5 shown. In such a configuration, the amplitude of the current with which the first to fourth drive units 131 to 134 which represent coils are supplied, adjusted so that the desired attraction and / or repulsion between the first to fourth drive units 131 to 134 and the magnet 135 and 136 is generated, whereby the correction lens module 110 through the first to fourth drive units 131 to 134 is moved.

In this regard, the number of magnets may be two, instead of four, corresponding to the number of first to fourth drive units 131 to 134 be. In other words, the first drive unit 131 and the third drive unit 133 may be arranged to be a magnet 135 correspond, and the second drive unit 132 and the fourth drive unit 134 may be arranged so as to be the other magnet 136 which simplifies the configuration of the handshake correction device. In this case, as in the 3 to 5 shown, the first drive unit 131 and the third drive unit 133 on a first side of the correction lens 111 arranged, and the second drive unit 132 and the fourth drive unit 134 are on a second side of the correction lens 111 arranged.

It is necessary that the correction lens module 110 close to the base 120 is applied. In the prior art, a spring is used for this purpose. However, when using a spring, due to the decrease in the spring's elasticity, the correction lens module may over time 110 no longer close to the base 120 issue. To prevent this problem, yokes 130a and 130b in the handshake correction apparatus according to the present embodiment of the present invention. The yokes 130a and 130b are on a first side of the correction lens support plate 113 arranged such that an attraction between the correction lens support plate 113 and the magnet 135 and 136 placed on a second side of the corrective lens backing plate 113 are arranged is generated. Accordingly, if the yokes 130a and 130b at the base 120 abut, the correction lens module 110 naturally close to the base. In particular, since the magnets 135 and 136 must be present to the correction lens module 110 as described above, by adding the yokes 130a and 130b the correction lens module 110 taking advantage of the attraction between the magnets 135 and 136 and the yokes 130a and 130b is generated, effective to the base 120 be created.

If the correction lens module 110 is shaken due to a movement caused by an external impact, the correction lens module 110 through between the magnets 135 and 136 and the yokes 130a and 130b on the corrective lens support plate 113 generated attraction can be returned to its original position. Likewise, when centering the position of the correction lens module 110 by supplying the first to fourth drive units 131 to 134 Electricity consumes electricity by taking advantage of the attraction between the yokes 130a and 130b and the magnet 135 and 136 be significantly reduced.

6A Fig. 13 is an exploded perspective view showing an example of a handshake correction apparatus according to another embodiment of the present invention. The device for handshake correction of the example of 6 differs from the previous embodiment in that a cover 160 present with the base 120 is connected and the correction lens module 110 covers. A first detection unit 141 indicating the movement of the corrective lens support plate 113 detected along a first axis (x-axis), and a second detection unit 142 indicating the movement of the corrective lens support plate 113 detected along a second axis (y-axis) are on the cover 160 arranged. Each of the first and second detection units 141 and 142 may include a neck sensor which detects the movement and / or position of the correction lens backing plate 113 detects, utilizing the principle that a current and / or a voltage which is induced according to the intensity of a magnetic field changes. However, the first detection unit 141 and the second detection unit 142 included in the handshake correction apparatus according to the present embodiment of the present invention is not limited to those described above; they can also have other structures.

When the first detection unit 141 and the second detection unit 142 Hall sensors included, these are required magnets sary. Since, as described above, the magnets 135 and 136 in the correction lens module 110 for operating the first to fourth drive units 131 to 134 present to the correction lens support plate 113 to move, the first detection unit 141 and the second detection unit 142 the movement of the correction lens support plate 113 using the magnets 135 and 136 detect. In this way, no additional magnets are required, and the configuration of the handshake correction device can be simplified. In this case, the first drive unit 131 and the third drive unit 133 on a first side of the correction lens 111 formed, and the second drive unit 132 and the fourth drive unit 134 are on a second side of the correction lens 111 educated; the first detection unit 141 may be arranged on the first side, and the second detection unit 142 can be arranged on the second side. Alternatively, the first detection unit 141 be arranged on the second side and the second detection unit 142 can be arranged on the first page.

7 FIG. 15 is a perspective view illustrating an example of a handshake correction apparatus according to another embodiment of the present invention. FIG. The device for handshake correction of the example of 7 is a device for handshake correction with integrated closure, in which a closure 151 , which points to the correction lens 111 shielding incident light, and a shutter drive unit 153 that the shutter 151 for shielding from the correction lens 111 can move incident light integrally formed as a unit. That is, when the shutter 151 through the shutter drive unit 153 is moved and thus near the correction lens 111 is positioned, light can pass through the correction lens 111 be prevented. In 7 are two closures 151 and two shutter drive units 153 shown; however, the present invention is not limited thereto. Alternatively, for example, a closure 151 and a shutter drive unit 153 on a first side of the correction lens support plate 113 may be disposed, and an ND filter and an ND filter drive unit may be disposed on a second side of the correction lens support plate 113 be arranged.

In the handshake correction apparatus according to the present embodiment of the present invention, the shutter drive unit is 153 such that a first detection unit (not shown) and a second detection unit (not shown) do not overlap each other along the optical axes. As described above with respect to the first to fourth drive units (not shown), the shutter drive unit 153 Coils include and regulate the flow of current through the coils, thereby generating a force around the closure 151 to move by interaction between the coil and the magnets, which are arranged adjacent to the coil. The first detection unit and the second detection unit may include Hall sensors that monitor the movement and / or position of the correction lens support plate 113 detect, utilizing the principle that a current and / or a voltage which is induced in accordance with the intensity of a magnetic field changes. When the shutter drive unit 153 is arranged adjacent to the first detection unit and / or the second detection unit, the first detection unit and / or the second detection unit may have a malfunction. However, in the handshake correction apparatus according to the present embodiment of the present invention, the shutter drive unit is 153 is disposed so as not to overlap with the first detection unit (not shown) and the second detection unit (not shown) along the optical axis, whereby malfunction of the first detection unit and the second detection unit can be effectively prevented.

8th Fig. 16 is a perspective view showing an example of a digital still camera according to an embodiment of the present invention. According to the example of 8th For example, the digital camera according to the present embodiment of the present invention includes a self-timer lamp 211 , a flash 212 , a trigger button 213 , a sighting device 217 , a sensor for the amount of flash light 219 , an on / off switch 231 , a lens unit 220 and a remote reception unit 241 ,

In self-timer mode, the self-timer lamp will turn on 211 during a setup time from a time when the shutter button is pressed 213 is pressed until a time when the image is taken. The sensor for the amount of flash 219 senses the amount of light when the flash 212 is operated, and inputs the amount of light via a (not shown) microcontroller in the (not shown) processor of the digital camera. The unit for remote reception 241 receives a command signal, such as a photograph command signal, from a remote controller (not shown) to input the command signal through the microcontroller into the processor of the digital camera.

The digital camera may include any of the handshake correction devices according to the above-described embodiments and / or modified examples of the embodiments. In this way, a decrease in the sharpness of the images caused by a vibration of the digital camera, such as a handshake of the photographer, caused be prevented. In particular, a decrease in the sharpness of the images caused during the operation of the handshake correction device can be effectively prevented as compared with conventional handshake prevention devices.

According to the Device for handshake correction and the digital camera, which is the device for handshake correction according to the present Contains invention, a decrease in Schär fe of the pictures used when photographing pictures of the digital camera, are significantly reduced.

The The present invention has been particularly appreciated with reference to exemplary Embodiments shown and described; a specialist in the field, however, recognizes that various changes in shape and detail can be made without the scope of the present invention as defined by the following Claims is left.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - KR 10-2008-0051067 [0001]

Claims (12)

Handshake correction device comprising: one Correction lens module comprising a correction lens and a correction lens support plate, which carries the correction lens comprises; One Base, which the correction lens support plate along a first Axis perpendicular to an optical axis of the correction lens is, and along a second axis perpendicular to the optical axis and the first axis is movable; first and second drive units, which the correction lens support plate move so that the correction lens support plate along the first axis can be moved; and third and fourth Drive units which the correction lens support plate move so that the correction lens support plate along the second axis can be moved, where the first and second drive units are arranged such that a line of action the driving force applied to the corrective lens support plate the first and second drive units are exercised, passing through a center of mass of the correction lens module, and the third and fourth drive units are arranged in such a way are that a line of action of the driving force acting on the corrective lens support plate is exercised by the third and fourth drive units, passes through a center of mass of the correction lens module. Device for handshake correction according to claim 1, wherein the center of mass of the correction lens module along the optical axis of the correction lens is positioned. Device for handshake correction according to claim 1, wherein the line of action of the driving force acting on the correction lens support plate is exercised by the first drive unit, and the Line of action of the driving force acting on the corrective lens carrier plate is exercised by the second drive unit, respectively parallel to the first axis. Device for handshake correction according to claim 1, wherein the line of action of the driving force acting on the correction lens support plate is exercised by the third drive unit, and the Line of action of the driving force acting on the corrective lens carrier plate is exercised by the fourth drive unit, respectively parallel to the second axis. Device for handshake correction according to claim 1, wherein the correction lens module further comprises a magnet, which is arranged on the correction lens carrier plate, and the first to fourth drive units comprise coils that are arranged on the base. Device for handshake correction according to claim 5, which further comprises a yoke, which is based on the magnet is arranged, wherein the correction lens support plate between the yoke and the base, and the correction lens module by attraction between the magnet and the yoke close to the base is applied. Device for handshake correction according to claim 1, wherein the first drive unit and the third drive unit are arranged on a first side of the correction lens, and the second drive unit and the fourth drive unit on a second side of the correction lens are arranged. Device for handshake correction according to claim 1, further comprising a cover connected to the base, to cover the correction lens module, the cover a first detection unit, which controls the movement of the correction lens carrier plate detected along the first axis, and a second detection unit, which the movement of the correction lens support plate along the second axis detected includes. Device for handshake correction according to claim 8, wherein each of the first and second detection units is a Hall sensor includes. Device for handshake correction according to claim 8, wherein the first drive unit and the third drive unit are arranged on a first side of the correction lens, and the second drive unit and the fourth drive unit on a second side of the correction lens are arranged, and the first Detection unit is arranged on the first page and the second Detection unit arranged on the second side of the correction lens or the first detection unit is arranged on the second side and the second detection unit on the first side of the correction lens is arranged. Device for handshake correction according to claim 10, which further comprises: a closure, which on the correction lens can shield incident light; and a Shutter drive unit that moves the shutter to open to shield the correction lens from incident light, the Shutter drive unit is arranged such that the positions the first detection unit and the second detection unit, viewed along the optical axis, do not overlap. Digital camera, which the Vorrich tion for handshake correction according to claim 1.